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Mitsubishi Chemical Corporation (MCC; Head office: Chiyoda-ku, Tokyo; President: Masayuki Waga) and its subsidiary Mitsubishi Chemical Methacrylates (MCM; Representative: Hitoshi Sasaki) have developed a manufacturing technology for MMA (methyl methacrylate) monomers that uses plant-derived materials and have begun designing a pilot plant.
The two companies (Group) define MMA monomers manufactured by the following three methods as Sustainable MMA and are working on the development of its manufacturing technology.
1.Molecular recycling that collects, decomposes and reuses used acrylic resin *
2.New manufacturing technology that applies plant-derived raw materials to the existing MMA monomer manufacturing process
3.New manufacturing technology to directly manufacture MMA monomers from plant-derived raw materials by fermentation
Promising results using method No. 2 have prompted the Group to begin the design process for a new pilot plant. Applying plant-derived raw materials to the existing process will enable the production of MMA using 100% bio-derived carbon. The pilot plant will be put into operation in fiscal year and, after demonstrating the technologys viability, the goal is to apply it to existing commercial-scale plants in .
The Group is also developing innovative catalysts and processes to improve productivity in its existing MMA monomer manufacturing technologies, striving to reduce environmental impact by reducing energy consumption and emissions during manufacturing.
MMA is a raw material for acrylic resin used in automobile lamp covers, signboards, aquarium tanks, paints, building materials and many other items. Global demand for MMA has exceeded 3.6 million tons and is expected to continue to grow at the same level as GDP in every country.
As the worlds No.1 manufacturer with the top share in the MMA and acrylic resin industry, the Group will pursue the potential of this business, work with stakeholders around the world to reduce the environmental burden of the entire supply chain and seek to actively lead the efforts to realize a circular economy.
* The phrase molecular recycling is used because it points to depolymerizing the collection of molecules found in acrylic resin to regain the original functionality of the MMA molecules it contains.
-Press release dated May 24, , titled Construction of Verification Facilities and Implementation of Verification Testing to Commercialize Acrylic Resin Molecular Recycling Operations.
-Press release dated December 9, , titled Successful trial results for acrylic resin chemical recycling with Agilyx.
About Mitsubishi Chemical Corporation
Mitsubishi Chemical Corporation creates innovative solutions globally based on our core values of sustainability, health and comfort, striving for the well-being of people, society and our planet Earth. We call this KAITEKI. Learn more at www.m-chemical.co.jp/en.
About Mitsubishi Chemical Methacrylates
Mitsubishi Chemical Methacrylates (MCM) is the global Methacrylates Division of Mitsubishi Chemical. With manufacturing sites, sales offices and distribution networks stretching across Asia, the Americas and Europe, MCM creates products that improve quality of life around the world, every single day. Learn more at www.mcc-methacrylates.com.
For further information, contact:
Communication Division
Mitsubishi Chemical Corporation
: +81-3--
Not to be confused with methyl acrylate
Methyl methacrylate (MMA) is an organic compound with the formula CH2=C(CH3)COOCH3. This colorless liquid, the methyl ester of methacrylic acid (MAA), is a monomer produced on a large scale for the production of poly(methyl methacrylate) (PMMA).[4]
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MMA was discovered by Bernhard Tollens and his student W. A. Caspary in ,[5] who noticed and described its tendency to change into a clear, hard, transparent substance especially in sunlight.[6] Studies on acrylic esters slowly developed until the Staudinger's theory of macromolecules and his research into the nature of polyacrylates allowed to control the polymerization. Company Rohm and Haas founded by German chemist Otto Röhm, who investigated the topic for three decades, was finally able to start its industrial production in .[7]
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Given the scale of production, many methods have been developed starting from diverse two- to four-carbon precursors.[4][8] Two principal routes appear to be commonly practiced.
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The principal route begins with the condensation of acetone and hydrogen cyanide:
Sulfuric acid then hydrolyzes acetone cyanohydrin (ACH) to a sulfate ester-adduct, which is cracked to the ester:[9]
Methanolysis gives ammonium bisulfate and MMA:
This technology affords more than 3 billion kilograms per year, and the economics have been heavily optimized.[10][11] Nevertheless, the ACH route coproduces substantial amounts of ammonium sulfate: roughly 1.1 kg/(kg MMA). Disposal of the salt is very energy intensive.
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The first stage involves carboalkoxylation of ethylene to produce methyl propionate (MeP):[12]
The MeP synthesis is conducted in a continuous-stirred tank reactor at moderate temperature and pressure using proprietary agitation and gas-liquid mixing arrangement.
In a second set of reactions, MeP is condensed with formaldehyde in a single heterogeneous reaction step to form MMA:[13]
The reaction of MeP and formaldehyde takes place over a fixed bed of catalyst. This catalyst, caesium oxide on silica, achieves good selectivity to MMA from MeP. The formation of a small amount of heavy, relatively involatile compounds poisons the catalyst. The coke is easily removed and catalyst activity and selectivity restored by controlled, in-situ regeneration. The reactor product stream is separated in a primary distillation so that a crude MMA product stream, free from water, MeP and formaldehyde, is produced. Unreacted MeP and water are recycled via the formaldehyde dehydration process. MMA (>99.9%) is purified by vacuum distillations. The separated streams are returned to the process; there being only a small heavy ester purge stream, which is disposed of in a thermal oxidizer with heat recovered for use in the process.
In , Lucite International commissioned an Alpha MMA plant on Jurong Island in Singapore. This process plant was cheaper to build and run than conventional systems, produces virtually no waste and the feedstocks can even be made from biomass.
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Ethylene is first hydroformylated to give propanal, which is then condensed with formaldehyde to produce methacrolein, The condensation is catalyzed by a secondary amine. Air oxidation of methacrolein to methacrylic acid completes the synthesis of the acid:[10]
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Want more information on MMA Plant? Feel free to contact us.
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O2 CH2=C(CH3)CO2H[
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As developed by Atochem and Röhm, isobutyric acid is produced by hydrocarboxylation of propene, using HF as a catalyst:
Oxidative dehydrogenation of the isobutyric acid yields methacrylic acid. Metal oxides catalyse this process:[10]
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Using Reppe chemistry, methyl acetylene is converted to MMA. As developed by Shell, this process produces MMA in one step reaction with 99% yield with a catalyst derived from palladium acetate, phosphine ligands, and Bronsted acids as catalyst:[10]
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The reactions by the direct oxidation method consist of two-step oxidation of isobutylene or TBA with air to produce methacrylic acid and esterification by methanol to produce MMA.[10]
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O2 CH2=C(CH3)CO2HA process using isobutylene as a raw material has been commercialized by Escambia Co. Isobutylene is oxidized to provide α-hydroxy isobutyric acid. The conversion uses N2O4 and nitric acid at 510 °C in the liquid phase. After esterification and dehydration MMA is obtained. Challenges with this route, aside from yield, involve the handling of large amounts of nitric acid and NOx. This method was discontinued in after an explosion at an operation plant.[10]
Methacrylonitrile (MAN) process[
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MAN can be produced by ammoxidation from isobutylene:
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O2 CH2=C(CH3)CN + 3 H2OThis step is analogous to the industrial route to acrylonitrile, a related commodity chemical. MAN can be hydrated by sulfuric acid to methacrylamide:
Mitsubishi Gas Chemicals proposed that MAN can be hydrated to methacrylamide without using sulfuric acid and is then esterified to obtain MMA by methylformate.[10]
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Asahi Chemical developed a process based on direct oxidative esterification of methacrolein, which does not produce by-products such as ammonium bisulfate. The raw material is tert-butanol, as in the direct oxidation method. In the first step, methacrolein is produced in the same way as in the direct oxidation process by gas phase catalytic oxidation, is simultaneously oxidized and is esterified in liquid methanol to get MMA directly.[10]
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The principal application, consuming approximately 75% of the MMA, is the manufacture of polymethyl methacrylate acrylic plastics (PMMA). Methyl methacrylate is also used for the production of the co-polymer methyl methacrylate-butadiene-styrene (MBS), used as a modifier for PVC. Another application is as cement used in total hip replacements as well as total knee replacements. Used as the "grout" by orthopedic surgeons to make the bone inserts fix into bone, it greatly reduces post-operative pain from the insertions but has a finite lifespan. Typically the lifespan of methylmethacrylate as bone cement is 20 years before revision surgery is required. Cemented implants are usually only done in elderly populations that require more immediate short term replacements. In younger populations, cementless implants are used because their lifespan is considerably longer.[14] Also used in fracture repair in small exotic animal species using internal fixation.
MMA is a raw material for the manufacture of other methacrylates. These derivatives include ethyl methacrylate (EMA), butyl methacrylate (BMA) and 2-ethyl hexyl methacrylate (2-EHMA). Methacrylic acid (MAA) is used as a chemical intermediate as well as in the manufacture of coating polymers, construction chemicals and textile applications.[15]
Wood can be impregnated with MMA and polymerized in situ to produce stabilized wood.
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In terms of the acute toxicity of methyl methacrylate, the LD50 is 710 g/kg (oral, rat). It is an irritant to the eyes and can cause redness and pain.[16][17] Irritation of the skin, eye, and nasal cavity has been observed in rodents and rabbits exposed to relatively high concentrations of methyl methacrylate. Methyl methacrylate is a mild skin irritant in humans and has the potential to induce skin sensitization in susceptible individuals.[18][19]
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For more information, please visit MEG Plant.